An armor module and an explosive material therefore, which explosive material is normally retained at a less sensitive position, and upon demand it is modified into a more sensitive position, where its initiation ability is upgraded and wherein the modification is carried out by heating the explosive material.
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1. A method for modifying the sensitivity of an explosive material having a normal less sensitive state and a more sensitive state, the method, comprising:
providing a less sensitive explosive material that is less sensitive in its normal state;
applying a flexible sheet adjoining the explosive material, the flexible sheet comprising conductive elements embedded therein and arranged in a predefined pattern; and
heating at least a portion of the less sensitive explosive material in its less sensitive normal state to thereby modify its sensitivity to that of its more sensitive state, to produce a more sensitive explosive material,
wherein the more sensitive explosive material has an initiation ability or functional ability that is upgraded from that of its normal less sensitive state.
3. A method for modifying the sensitivity of an explosive material having a normal less sensitive state and a more sensitive state, the method, comprising:
providing a less sensitive explosive material that is less sensitive in its normal state;
embedding in the less-sensitive explosive material one or more thermocouples for providing an indication of temperature so as to obtain indicia of its sensitivity level or whether it is in a ‘safe’ or ‘armed’ position; and
heating at least a portion of the less sensitive explosive material in its less sensitive normal state to thereby modify its sensitivity to that of its more sensitive state, to produce a more sensitive explosive material,
wherein the more sensitive explosive material has an initiation ability or functional ability that is upgraded from that of its normal less sensitive state.
4. A method for modifying the sensitivity of an explosive material, comprising:
providing a less sensitive explosive material that is less sensitive in its native state, having a first less sensitive native state and a more sensitive modified state, the less sensitive explosive material having an initiation ability or a functional ability;
applying a flexible sheet adjoining the explosive material, the flexible sheet comprising conductive elements embedded therein and arranged in a predefined pattern; and
heating the less sensitive explosive material in its less sensitive native state under conditions sufficient to modify its sensitivity to that of its more sensitive modified state to produce a more sensitive material,
wherein the initiation ability or functional ability of the more sensitive explosive material is upgraded from that of its less sensitive native state.
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The present invention relates to altering sensitivity of an explosive material so as to control its sensitivity between different states for different applications.
High performance explosive compositions are long known and it is a goal for scientists to find new explosive compositions which can be defined as both low impact and shock sensitive, though offer high energy explosive performance. A combination of these properties offers higher transportation, storage and handling safety whilst not deteriorating the overall performance, of an explosive and an article holding it. For example, when applied in armor modules higher survivability is obtained, however without performance reduction, when compared to readily available explosive compositions of similar energetic properties.
Attempts have been made to desensitize solid high explosives, e.g. by mixing one or more energetic materials, relatively sensitive, with much less sensitive or with inert materials. The hope was to reduce the overall explosive sensitivity with increasing safety, and without significant effect on the overall performance of the mixture.
On the other hand, there are processes which successfully make insensitive explosives more sensitive. For example, some commercial slurry explosives are extremely insensitive which allows them to be safely transported through populated areas. When the explosive is emplaced, it is sensitized by mixing in a sensitizing agent, e.g. tiny glass micro-spheres (micro balloons).
A method for enhancing stability of high explosives is disclosed in U.S. Pat. No. 5,067,995 to Nutt, wherein the stability of porous solid high explosives, for purposes of transport or storage, is enhanced by reducing the sensitivity to shock initiation of a reaction that leads to detonation. The pores of the explosive down to a certain size are filled under pressure with a stable, low melt temperature material in liquid form, and the combined material is cooled so the pore filling material solidifies. The stability can be increased to progressively higher levels by filling smaller pores. The pore filling material can be removed, at least partially, by reheating above its melt temperature and drained off so that the explosive is again suitable for initiation.
It is an object of the present invention to provide an explosive material which is (normally retained at a less sensitive position, namely a position at which it performs as initially intended, and upon demand it is modified into a more sensitive position, where its initiation ability is upgraded.
The arrangement includes converting a substantially insensitive composition into a sensitive composition, as well as upgrading sensitivity levels.
The present invention also calls for a method and a system for upon-demand sensitizing a normally less sensitive explosive material by heating it. It is a further object to increase performance of an explosive material, and efficiency of an article carrying same, by heating the explosive material.
The present invention may be applied in a wide variety of applications, for example:
According to the present invention, the explosive material used is substantially less sensitive than an explosive material which would have been used so as to obtain an equivalent effect/functional result, though without heating.
For example, when applying explosive material for armors it is a main goal to increase its performance, whilst maintaining safety. The following are several examples illustrating improvements achieved by applying heat to explosive reactive armor articles/modules:
In the case of boosters, sensitivity of the explosive material may be altered from a ‘safe position’ wherein the explosive material is substantially insensitive and is not likely to initiate, into an ‘armed position’ wherein the explosive material is sufficiently sensitive so as to detonate upon initiation.
According to applications of the present invention the explosive material may be entirely heated, or only selective portions thereof, depending on a particular application. For example in the case of an explosive material used as in a booster, the explosive material may be heated at particular location only, for enabling initiation of the booster.
A potential heating member suited for applications according to the present invention, can have a wide range of heating capacity and temperature range. For example, in case of reactive armor cassettes/modules the heating capacity range is about 0.2-2.0 Watt/cm2, where the resultant heating of the explosive material is in the range of about 70-150° C. However, for other applications, the heat capacity may be dependant upon volume/mass, e.g. for warheads the heating capacity may be defined in volumetric units as Watt/cm3.
According to one particular embodiment of the present invention, there is provided a thermally isolating jacket over a reactive armor cassette/module. A thermal isolation member could be in the form of board or sheet material (e.g. foamed material). The isolating member could be also in the form of a double walled member holding a liquid or emulsion material. Moreover, other materials having substantially low heat conductivity, such as composite or ceramic materials, may also be used for thermal isolation, which in such cases the isolating material may also take part in the overall efficiency of the armor cassette/module. Thermal isolation will on one hand improve heating efficiency of the explosive material in the armor cassette/module, and on the other hand reduce the temperature at the vicinity of the reactive cassette/module (namely reduce heat within a vehicle fitted with a system according to the invention and thereby also reduce the thermal stamp of the vehicle).
According to various embodiments of the invention the explosive material is heated by a heating layer, such as a flexible sheet embedding therein conductive elements arranged in a pattern corresponding with a particular application, and adjoining the explosive material (embedded therein, bearing against or neighboring the explosive material, or bearing against an intermediate adjoining conductive material). One embodiment is a flexible elastomeric sheet.
According to a particular embodiment of the invention, the heating element is integrated with the explosive material during its manufacturing process, or later, e.g. by weaving, pressing, molding, etc. the heating elements into the explosive material.
The rate of heating the explosive material depends on several factors, such as, type of the explosive used, type of application, nature of threat, etc. For some applications sequential heating may be required, owing to energy consumption and thermal considerations.
According to another embodiment of the invention, one or more thermocouples are embedded in the explosive material for providing indication regarding temperature of the explosive material, so as to obtain indicia of its sensitivity level, and/or whether the explosive material is in its ‘safe’ or ‘armed’ position.
According to a further modification, there is provided a carrier board fitted with a heat-exchanging system and bearing a reactive armor being in heat-transfer association therewith. Optionally, the entire assembly or portions thereof, are thermally isolated, as discussed hereinbefore. For example, the heat-exchanging system may utilize heat of cooling liquids, or exhaust gases of an engine of a vehicle, e.g. a battle vehicle fitted with a reactive armor according to the invention. Still another option is utilizing Peltier heating elements.
In order to understand the invention and to see how it may be carried out in practice, some embodiments will now be described, by way of non-limiting examples only, with reference to the accompanying drawings, in which:
In
In
As can be seen in
It is noticed that the armor module may include several cassettes and each cassette may be multi-layered. Furthermore, the thickness and component materials of each cassette may differ depending on the particular design of the reactive armor.
Furthermore, in an application comprising several cassettes in an armor module, the heating elements may be designed to yield different heat capacity for each of the cassettes, e.g. corresponding with the thickness of the explosive material and of the plates. It is also possible to sequentially heat the cassettes at a desired sequence.
According to other modifications, not illustrated, one or more of the cassettes fitted in a reactive module may comprise more than one layer of explosive material intermediately disposed between layers of metal, rubber, ceramic material, composite material, etc., wherein the thickness of such plates may be similar or different, as per different embodiments.
Turning now to
The heat exchanger 44 comprises an inlet conduit 46 coupled to a source of hot fluid (e.g. cooling liquid of an engine of the vehicle 10 or, to a gas exhaust system thereof), and a plurality of undulating heat pipes 48 terminating at an outlet tube 50, which is either connected back to the heating source (e.g. in the case of a cooling liquid system) or out to the atmosphere (in case of a gas exhaust system). The arrangement is such that fluid flowing through conduits 48 transfers heat to the heating surface 52 of the heat exchanger 44, which in turn transfers heat to the cassette plate 58B and in turn to the explosive material 56 within the armor module 42 (in this case, the explosive material 56 is disposed between two conductive plates (e.g. metal plates 58A and 58B).
The arrangement in accordance with the present invention is such that heat is controllably and selectively applied to the reactive armor module so as to increase its efficiency between different sensitivity levels.
By one example a reactive armor module is heated so as to change its efficiency between a so-called safe position, namely a position at which the explosive material is insufficiently sensitive to initiate by a kinetic projectile, and a so-called armed position, namely such that upon striking by a kinetic projectile the explosive material will detonate to obtain the required protective effect.
In the schematic graph of
Line II illustrates a self limiting explosive material (fitted in SLERA) which at the normal, unheated position, will react locally against a hollow charge (namely, the explosive material will react at a restricted area only) whilst upon heating thereof will result in enhancement of the reaction zone up to complete detonation of the explosive material within the reactive armor. Heating may be, for example, up to 150° C.
Line III represents an explosive material, e.g. LBR6, which at the normal, non-heated position will detonate completely whilst upon heating up to about 150° C. will significantly improve the efficiency of the armor module holding the explosive material.
In
An advantage of this system is that the detonator 88 may be permanently fixed to the booster 80 and its arming may be readily obtained by heating. This is in contrast to the need in some known systems to keep the detonator separate from the booster and hollow charge (for safety reasons) unless it is to be used.
Whilst some embodiments have been described and illustrated with reference to some drawings, the artisan will appreciate that many variations are possible which do not depart from the general scope of the invention, mutatis, mutandis.
Friling, Samuel, Hanina, Erez, Keren, Benjamin, Cohen-Arazi, Yael
Patent | Priority | Assignee | Title |
10670375, | Aug 14 2017 | GOVERNMENT OF THE UNITED STATES, AS REPRESENTED BY THE SECRETARY OF THE ARMY | Adaptive armor system with variable-angle suspended armor elements |
Patent | Priority | Assignee | Title |
4522190, | Nov 03 1983 | University of Cincinnati | Flexible electrochemical heater |
4796533, | Jun 01 1984 | ETI CANADA INC | Primer assembly |
4893563, | Dec 05 1988 | The United States of America as represented by the Secretary of the Navy | Monolithic RF/EMI desensitized electroexplosive device |
5067995, | Jun 15 1989 | The United States of America as represented by the United States | Method for enhancing stability of high explosives, for purposes of transport or storage, and the stabilized high explosives |
5147476, | Mar 12 1990 | ORICA TRADING PTY LIMITED | Delay composition and device |
6209457, | Aug 13 1998 | Technology Commercialization Corp. | Method and preformed composition for controlled localized heating of a base material using an exothermic reaction |
6293201, | Nov 18 1999 | The United States of America as represented by the Secretary of the Navy | Chemically reactive fragmentation warhead |
6343000, | Apr 21 1998 | Toshiba Hokuto Electronics Corporation | Ignition device and method for manufacturing thereof |
7089861, | Jan 28 2003 | HIRTENBERGER-SCHAFFLER AUTOMOTIVE ZUNDER GES M B H | Heating element for igniting pyrotechnic charge |
20040200378, | |||
20070240600, | |||
20080251170, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Jun 18 2007 | Rafael Armament Development Authority Ltd. | (assignment on the face of the patent) | / | |||
Jun 18 2007 | KEREN, BENJAMIN | Rafael Armament Development Authority Ltd | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019575 | /0562 | |
Jun 18 2007 | COHEN-ARAZI, YAEL | Rafael Armament Development Authority Ltd | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019575 | /0562 | |
Jun 18 2007 | FRILING, SAMUEL | Rafael Armament Development Authority Ltd | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019575 | /0562 | |
Jun 18 2007 | HANINA, EREZ | Rafael Armament Development Authority Ltd | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 019575 | /0562 |
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